Interchangeable lens, camera body, and camera system

ABSTRACT

An interchangeable lens has a zoom lens, a zoom driver operable to drive the zoom lens along an optical axis, a focus lens, a focus driver operable to drive the focus lens along the optical axis, and a storage unit operable to store link information which links position information indicating a position of the zoom lens on the optical axis with information about a variation in magnification caused by the focus lens advancing and retreating on the optical axis with the zoom lens located at the position indicated by the position information.

BACKGROUND

1. Technical Field

The technical field relates to an interchangeable lens, a camera body,and a camera system, and particularly relates to a camera body whichperforms autofocus control in recording of moving image, aninterchangeable lens compatible with the camera body, and a camerasystem having the camera body and the interchangeable lens.

2. Related Art

JP-A-4-280239 discloses a camera apparatus of interchangeable lens typehaving a camera unit and a lens unit detachably mountable to the cameraunit. The lens unit has a drive system relating to automatic focusregulation and automatic exposure control. Further, the lens unit hasstatus information about the lens unit. In this camera apparatus,various control information and the status information are communicatedbetween the camera unit and the lens unit, so that the camera unitcontrols the lens unit.

In order to realize autofocus operation in recording of moving images,wobbling control is performed. In the wobbling control, while a focuslens is being advanced and retreated to an optically axial direction bya very short distance and a focus direction is being detected, the focuslens is moved to a direction of a focus position. Further, in a lensunit having a zoom lens and a focus lens, when the focus lens is movedwith a focus state being maintained, accordingly the zoom lensoccasionally moves. In such a lens unit, when the above wobbling controlis performed, a field angle periodically fluctuates by small oscillationof the focus lens. As the zoom lens is closer to a wide-angle side, thefluctuation becomes more remarkable. Therefore, when the wobblingcontrol is performed during recording of moving images, the field angleof the moving images recorded by the imaging device changes, and thusthe images become ugly for users. In the conventional camera apparatusesof interchangeable lens type (for example, the camera apparatus ofinterchangeable lens type disclosed in the JP-A-4-280239), when movingimages are recorded, automatic focus regulation cannot suitablyperformed for every state of the zoom lens, and thus the above problemscaused by the wobbling control cannot be solved.

SUMMARY

An object is to provide an interchangeable lens, a camera body and acamera system which can perform automatic focus operation suitablyaccording to a state of a zoom lens when recording moving images.

In order to solve above described problem, an interchangeable lensincludes: a zoom lens operable to change a size of a subject image; azoom driver operable to drive the zoom lens along an optical axis; afocus lens operable to change a focus state of the subject image; afocus driver operable to drive the focus lens along the optical axis;and a storage unit operable to store link information which linksposition information indicating a position of the zoom lens on theoptical axis with information about a variation in magnification causedby the focus lens advancing and retreating on the optical axis.

A camera body to which the above interchangeable lens is mountable,includes: a first obtaining unit operable to obtain the link informationfrom the interchangeable lens; a second obtaining unit operable toobtain information about the position of the zoom lens on the opticalaxis; a generating unit operable to generate a control signal forcontrolling the focus driver based on the link information obtained bythe first obtaining unit and the information about the position of thezoom lens obtained by the second obtaining unit; and a transmission unitoperable to transmit the control signal generated by the generating unitto the interchangeable lens.

A camera system has the interchangeable lens and the camera body.

According to the above configurations, the interchangeable lens storeslink information which links information about a position of the zoomlens on an optical axis with information about a variation inmagnification, and the camera body controls driving of the focus lensbased on the link information obtained from the interchangeable lens anda position of the zoom lens on the optical axis in recording of movingimages. As a result, when a determination is made that the variation inmagnification of the zoom lens becomes large, the state of the wobblingcontrol can be suitably controlled. Therefore, suitable autofocuscontrol can be performed according to the state of the zoom lens.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating a camera system according tofirst and second embodiments.

FIG. 2 is a typical diagram describing wobbling control.

FIG. 3 is a typical diagram describing hill climbing AF control.

FIG. 4 is a diagram illustrating a variation in magnification.

FIG. 5 is a diagram illustrating link information.

FIG. 6 is a typical diagram describing magnification variation ratio.

FIG. 7 is a diagram illustrating transmission/reception of signals in arecording preparation operation of a camera system.

FIG. 8 is a timing chart illustrating transmission/reception of signalsbetween the camera body and the interchangeable lens in the wobblingcontrol.

FIG. 9 is a flowchart illustrating an algorithm for determining anamplitude in the wobbling control.

FIG. 10 is a flowchart illustrating an algorithm for determining a drivespeed in the hill climbing AF.

FIG. 11 is a flowchart illustrating another algorithm for determiningthe amplitude in the wobbling control.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments are described below with reference to the accompanyingdrawings.

1. First Embodiment 1-1. Outline

A camera system according to the first embodiment includes a camera bodyand an interchangeable lens which is mountable to the camera body. Thecamera system can record moving images. Further, when recording movingimages, the camera system can perform autofocus control.

The interchangeable lens according to the first embodiment stores linkinformation which links information about a position of a zoom lens onan optical axis with information about a variation in magnification. Thecamera body controls driving of a focus lens based on the linkinformation obtained from the interchangeable lens and the position ofthe zoom lens on the optical axis at the time of recording movingimages. As a result, the interchangeable lens, the camera body and thecamera system according to the first embodiment enable suitableautofocus control according to a state of the zoom lens in the recordingof the moving images.

1-2. Configuration

A configuration of the camera system according to the first embodimentis described with reference to FIG. 1. FIG. 1 illustrates theconfiguration of the camera system. The camera system 1 includes thecamera body 100 and the interchangeable lens 200. Configurations of thecamera body 100 and the interchangeable lens 200 are described below,respectively.

1-2-1. Configuration of Camera Body

The camera body 100 mainly includes a CCD image sensor 110, a liquidcrystal display (LCD) monitor 120, a camera controller 140, a body mount150, a power supply 160, and a card slot 170.

The camera controller 140 controls the entire camera system 1 (forexample, the CCD image sensor 110) according to an instruction from anoperating member such as a release button 130. The camera controller 140transmits a vertical synchronizing signal to a timing generator 112.Simultaneously, the camera controller 140 generates an exposuresynchronizing signal based on the vertical synchronizing signal. Thecamera controller 140 periodically transmits the generated exposuresynchronizing signal to a lens controller 240 via the body mount 150 anda lens mount 250 in a repeated manner. The camera controller 140 uses aDRAM 141 as a work memory in a control operation and an image processingoperation.

The CCD image sensor 110 captures a subject image incident via theinterchangeable lens 200 so as to generate image data. An AD converter111 digitizes the generated image data. The camera controller 140 givesvarious image processes to the digitized image data. The various imageprocesses include, for example, a gamma correction process, a whitebalance correction process, a flaw correction process, an YC conversionprocess, an electronic zoom process, and an image compression processsuch as a JPEG compression process.

The CCD image sensor 110 operates at timing controlled by the timinggenerator 112. The CCD image sensor 110 performs, for example, a stillimage capturing operation, a moving image capturing operation, and athrough image capturing operation. The through image means an image thatis not recorded in a memory card 171 after the capturing. The throughimage is mainly a moving image, and is displayed on the LCD monitor 120in order to determine a composition of recording a still image.

The LCD monitor 120 displays an image indicated by the display imagedata that is subjected to image process by the camera controller 140.The LCD monitor 120 can selectively display a moving image and a stillimage.

The memory card 171 can be mounted to the card slot 170. The card slot170 controls the memory card 171 based on control of the cameracontroller 140. The memory card 171 can store the image data generatedby the image process of the camera controller 140. The memory card 171can store, for example, a JPEG image file. Further, the memory card 171can output image data or an image file stored therein. The image data orthe image file output from the memory card 171 are processed by thecamera controller 140. For example, the camera controller 140 expandsthe image data or the image file obtained from the memory card 171 so asto generate display image data.

The power supply 160 supplies a power to be consumed in the camerasystem 1. The power supply 160 may be, for example, a dry battery or arechargeable battery. Further, the power supply 160 may supply a powerto the camera system 1 externally via a power-supply cord.

A mode dial 131 is a dial for changing a mode of the camera system 1. Auser operates the mode dial 131 so as to be capable of switching themode of the camera system 1 between a moving image recording mode and astill image recording mode.

The body mount 150 can be mechanically or electrically connected to thelens mount 250 of the interchangeable lens 200. The body mount 150 cantransmit/receive data to/from the interchangeable lens 200 via the lensmount 250. The body mount 150 transmits an exposure synchronizing signalreceived from the camera controller 140 to the lens controller 240 viathe lens mount 250. Further, the body mount 150 transmits the othercontrol signals received from the camera controller 140 to the lenscontroller 240 via the lens mount 250. The body mount 150 transmits thesignals received from the lens controller 240 to the camera controller140 via the lens mount 250. The body mount 150 supplies a power receivedfrom the power supply 160 to the entire interchangeable lens 200 via thelens mount 250.

1-2-2. Configuration of Interchangeable Lens

The interchangeable lens 200 mainly has an optical system, the lenscontroller 240, and the lens mount 250. The optical system of theinterchangeable lens 200 includes a zoom lens 210, an OIS lens 220, anda focus lens 230.

The zoom lens 210 is a lens for changing a magnification of a subjectimage formed by the optical system of the interchangeable lens 200. Thezoom lens 210 is composed of one or a plurality of lenses. A drivemechanism 211 includes a zoom ring or the like operable by the user, andtransmits a user's operation to the zoom lens 210 so as to move the zoomlens 210 along a direction of the optical axis of the optical system. Adetector 212 detects a drive amount of the drive mechanism 211. The lenscontroller 240 obtains a result detected by the detector 212 so as to becapable of recognizing a zoom magnification of the optical system.Further, the lens controller 240 obtains the result detected by thedetector 212 so as to be capable of recognizing the position of the zoomlens 210 on the optical system.

The OIS lens 220 is a lens for correcting blur of a subject image formedin the optical system of the interchangeable lens 200. The OIS lens 220moves to a direction where blur of the camera system 1 is compensated soas to reduce the blur of the subject image on the CCD image sensor 110.The OIS lens 220 is composed of one or a plurality of lenses. Anactuator 221 drives the OIS lens 220 in a plane vertical to the opticalaxis of the optical system under control of an OIS IC 223. The actuator221 can be realized by, for example, a magnet and a planar coil. Aposition detection sensor 222 is a sensor for detecting a position ofthe OIS lens 220 in the plane vertical to the optical axis of theoptical system. The position detection sensor 222 can be realized by,for example, a magnet and a Hall element. The OIS IC 223 controls theactuator 221 based on a detected result of the position detection sensor222 and a detected result of a blur detector such as a gyro sensor.

The focus lens 230 is a lens for changing a focus state of a subjectimage formed on the CCD image sensor 110 by the optical system. Thefocus lens 230 is composed of one or a plurality of lenses.

A focus motor 233 drives the focus lens 230 so that the focus lens 230advances and retreats along the optical axis of the optical system basedon control of the lens controller 240. As a result, the focus state of asubject image formed on the CCD image sensor 110 can be changed in theoptical system. Further, the focus motor 233 drives the focus lens 230so that the focus lens 230 slightly advances and retreats along theoptical axis of the optical system based on control of the lenscontroller 240. As a result, even when moving images are recorded, theautofocus control can be performed. A stepping motor can be used as thefocus motor 233 in the first embodiment. The focus motor 233 is not,however, limited to this, and can be realized by a servo motor, anultrasonic motor or the like.

The lens controller 240 controls the entire interchangeable lens 200(for example, the OIS IC 223 and the focus motor 233) based on a controlsignal from the camera controller 140. The lens controller 240 receivessignals from the detector 212 and the OIS IC 233 and the like so as totransmit them to the camera controller 140. The lens controller 240transmits/receives the signals to/from the camera controller 140 via thelens mount 250 and the body mount 150. The lens controller 240 uses aDRAM 241 as a work memory at the time of control. For example, the lenscontroller 240 receives an instruction of a wobbling operation from thecamera controller 140 so as to control the wobbling operation of thefocus lens 240. The wobbling control is a control to continuouslyperform the autofocus control by slightly advancing and retreating thefocus lens 230 along the optical axis while the camera system 1 isrecording a moving image.

A flash memory 242 saves programs and parameters to be used for thecontrol of the lens controller 240. The flash memory 242 saves, forexample, a control program for controlling the wobbling of the focuslens 230 and a program for performing the autofocus control in recordingof a still image (so-called hill climbing autofocus control). The hillclimbing autofocus control is a focusing method for moving the focuslens 230 along the optical axis and detecting a position where acontrast value of an image captured by the CCD image sensor 110 becomesthe largest in each position so as to move the focus lens 230 to thedetected position. The wobbling control and the hill climbing autofocuscontrol are described in detail below.

In the first embodiment, the flash memory 242 further saves linkinformation. The link information is information indicating a changerate of the magnification of a subject changing according to the focuslens 230 which slightly advances and retreats along the optical axiswhen the zoom lens 210 is located at a certain position of the opticalaxis. Details of the link information are described later.

1-2-3. Wobbling Control and Hill Climbing Autofocus Control

The wobbling control is first described with reference to FIG. 2. FIG. 2is a typical diagram describing the wobbling control. In FIG. 2, avertical axis indicates the position of the focus lens 230 on theoptical axis. A horizontal axis indicates a time axis. In FIG. 2, thefocus lens 230 repeats the slight advancing and retreating along theoptical axis and simultaneously moves gradually to a subject side. Inthe wobbling control, the camera system 1 advances and retreats thefocus lens 230 along the optical axis every capturing of an image forone frame. The advancing and retreating of the focus lens 230 are notperformed at a constant speed. The camera system 1 reduces the movingspeed of the focus lens 230 in a vicinity where the advancing directionof the focus lens 230 is changed (that is, near the focus position). Asa result, a moving image in which focus condition is approximatelyconstant can be recorded through the entire recording time.

Every time when the camera system 1 captures an image for 1 frame andgenerates image data, it calculates an evaluation value for theautofocus operation on the generated image data (hereinafter, “AFevaluation value”). For example, the following method is known. In thismethod, brightness signals are obtained from the image data generated bythe CCD image sensor 110, and high-frequency components of thebrightness signals on a screen are integrated so that an AF evaluationvalue is obtained. In such a manner, the camera system 1 calculates AFevaluation values in a state that the focus lens 230 is moved along thedirection of the optical axis to the subject side and in a state thatthe focus lens 230 is moved to the side of the CCD image sensor 110according to the generation of image data for two frames. By comparingthe two AF evaluation values, the camera system 1 determines whether thefocus lens 230 should be moved to the subject side or to the side of theCCD image sensor 110 at a later cycle. The camera system 1 advances andretreats the focus lens 230 along the optical axis so that a subjectimage is continuously focused at the time of recording a moving image.The lens controller 240 controls the focus motor 233 according to theacquisition of control signals indicating instructions of a movingdirection, a moving amount and an amplitude of the focus lens 230 fromthe camera body 100 via the lens mount 250.

The hill climbing autofocus control is described below with reference toFIG. 3. FIG. 3 is a typical diagram for describing the hill climbingautofocus control. In FIG. 3, a vertical axis indicates the AFevaluation value, and a horizontal axis indicates the position of thefocus lens 230 on the optical axis. The wobbling control is suitable forthe autofocus control in the recording of moving images, and on thecontrary, the hill climbing autofocus control is suitable mainly for theautofocus control in the recording of still images.

When the hill climbing autofocus control is performed, the camera system1 continuously drives the focus lens 230 in one direction such as eithera direction toward an infinity end or a direction toward a nearest endof the interchangeable lens 200. The camera system 1 continuouslycalculates the AF evaluation value periodically according to the driveof the focus lens 230. The camera system 1 continuously drives the focuslens 230 in one direction as long as the AF evaluation value increases.When the AF evaluation value stops increasing and starts decreasing, thecamera system 1 determines that the focus lens 230 passes through thefocus point, and drives the focus lens 230 in a reverse direction. As aresult, the camera system 1 moves the focus lens 230 to the focus point.The camera system 1 can obtain the focus state by driving the focus lens230 in such a manner.

1-2-4. Link Information

The link information is described below with reference to FIGS. 4, 5 and6. FIG. 4 is a typical diagram describing a variation in themagnification. FIG. 5 is a diagram illustrating the link information.FIG. 6 is a typical diagram describing magnification variation ratio.The interchangeable lens 200 stores a table about the link informationshown in FIG. 5 in the flash memory 242.

After a focus state is obtained with combining the zoom lens 210 and thefocus lens 230, when the focus lens 230 is moved, the magnificationchanges. For example, after the focus state is obtained, with the zoomlens 210 is positioned at a certain position on the optical axis of theinterchangeable lens 200, when the wobbling control of the focus lens230 is performed for autofocus in the recording of moving images or thefocus lens 230 is moved for autofocus in the recording of still images,the magnification changes. That is to say, in the case where thewobbling control of the focus lens 230 is performed for autofocus in therecording moving of images or the focus lens 230 is moved for autofocusin the recording of still images, a focal length of the interchangeablelens 200 changes, and thus the magnification changes. This is because asize of the subject image captured on the CCD image sensor 110 changeswhen the focal length of the interchangeable lens 200 changes.

As shown in FIG. 4, for example, when the focus lens 230 is located at aposition “x” on the optical axis, an image X is captured on the CCDimage sensor 110. In this state, when the wobbling control of the focuslens 230 is performed and the focus lens 230 is moved to a position “y”,an image Y is captured on the CCD image sensor 110. The magnification ofa subject in the image Y is lower than that in the image X (a brokenline in the image Y corresponds to the subject in the image X). Further,when the wobbling control of the focus lens 230 is performed and thefocus lens 230 is moved to a position “z”, an image Z is captured on theCCD image sensor 110. The magnification of the subject in the image Z ishigher than that in the image X (a broken line in the image Zcorresponds to the subject in the image X). When the wobbling control ofthe focus lens 230 is performed in such a manner, the magnification ofthe subject image captured on the CCD image sensor 110 changes.

The more an amplitude (swing width) in wobbling of the focus lens 230 isincreased, the more noticeable the variation in the magnification of thesubject image captured on the CCD image sensor 110 becomes. Thevariation in the magnification changes according to the position of thezoom lens 210 (close to a wide-angle side or a telephoto side). Althoughthe variation in the magnification changes according to characteristicsof the optical system, the variation in the magnification is higher onthe wide-angle side and is lower on the telephoto side in theinterchangeable lens 200 according to the first embodiment.

The link information is described below with reference to FIG. 5. Thelink information is management information which links the informationabout the position of the zoom lens 210 on the optical axis with theinformation indicating a change rate of the magnification (hereinafter,referred to as “magnification variation ratio”) caused by the wobblingcontrol of the focus lens 230 in the case that the zoom lens 210 islocated at the position. In the example of FIG. 5, the amplitude of thewobbling control is constant (for example, 80 μm), and the magnificationvariation ratio on the respective positions of the zoom lens isobtained. In the interchangeable lens 200, the position of the zoom lens210 on the optical axis is divided into 32 stages, and the zoom lens 210can be held on the respective positions. In FIG. 5, “the zoom position”indicates a position of the zoom lens 210 on the optical axis of theinterchangeable lens 200. When the zoom lens 210 is located at each of32 positions and the wobbling control of the focus lens 230 isperformed, an image that transmits through the interchangeable lens 200to be captured on the CCD image sensor 110 has the variation inmagnification which changes variously according to the positions of thezoom lens 210. In FIG. 5, “magnification variation ratio (%)” indicatesthe change rate of the magnification on the respective positions of thezoom lens 210.

The magnification variation ratio is obtained by a ratio of an amount ofmovement when one predetermined point in a region of an imagetransmitting through the interchangeable lens 200 to be captured on theCCD image sensor 110 in the wobbling control of the focus lens 230moves, to a length from a center point to the one predetermined point inthe CCD image sensor 110. This is concretely described with reference toFIG. 6. FIG. 6 illustrates an image that is captured by the CCD imagesensor 110 and is displayed on the LCD monitor 120. It is assumed thatone point in which the amount of movement is observed is “B”, and acenter point of the LCD monitor 120 is “A”, when the wobbling control ofthe focus lens 230 is performed. Further, it is assumed that a distancefrom the point A to the point B is “a”, and a distance of movement bythe point B in the wobbling control of the focus lens 230 is “b”. Inthis case, the magnification variation ratio is b/a. For example, in thetable shown in FIG. 5, when the position of the zoom lens 210 is “0”,b/a=0.2(%).

In the camera system 1 according to the first embodiment, one point inwhich the amount of movement is observed is the most corner portion onthe captured image (that is, the LCD monitor 120), but it is notnecessarily to the most corner portion. For example, it may be a rightportion or a left portion. In short, this one point may be any one pointseparated from the center.

In the camera system 1 according to the first embodiment, the movementof one point is observed so that the magnification variation ratio isdetermined in the case where the zoom lens 210 is located at thepredetermined position. However, the magnification variation ratio isnot necessarily determined by such a method. For example, movements of aplurality of points are observed, and the largest amount of movement ofany one of the points may be adopted as the magnification variationratio in the case where the zoom lens 210 is located at that position.

The interchangeable lens 200 according to the first embodiment managesthe magnification variation ratios for the respective positions of thezoom lens 210 as the link information, but does not have to have such aconfiguration. The interchangeable lens 200 may manage an amount ofmovement of a predetermined point displayed on the LCD monitor 120 forthe respective positions of the zoom lens 210 in the case of thewobbling control of the focus lens 230. In short, the interchangeablelens 200 may manage information indicating differences in the variationof the magnification on the respective positions of the zoom lens 210.

The interchangeable lens 200 according to the first embodiment divides amovable position into 32 points so as to manage the positions of thezoom lens 210, but does not necessarily manage in such a manner. Forexample, the movable position may be divided into 10 points, or may bedivided into 64 points, or may be divided into 100 points so as to bemanaged. In short, any method may be adopted as long as the position ofthe zoom lens 210 can be managed.

The interchangeable lens 200 according to the first embodiment is a zoomlens. However, the interchangeable lens 200 is not necessarily limitedto the zoom lens. For example, the interchangeable lens 200 may be asingle focus lens. In this case, the single focus lens may have onlyinformation about magnification variation ratios regardless of aposition of zoom lens as link information.

The interchangeable lens 200 according to the first embodiment saves thelink information in the flash memory 242. As a result, the magnificationvariation ratios on the respective positions of the zoom lens 210 can betransmitted to the camera body 100 in advance (before recording). As aresult, even when any interchangeable lens having any magnificationchange characteristics is mounted to the camera body 100, the camerabody 100 can transmit an instruction to the interchangeable lens 200 sothat wobbling control suitable for the respective positions of the zoomlens 210 is performed.

1-3. Operation 1-3-1. Recording Preparation Operation

The operation of the camera system 1 for recording preparation isdescribed. FIG. 7 illustrates timings of transmitting and receiving asignal in the recording preparation operation of the camera system 1according to the first embodiment.

When the interchangeable lens 200 is mounted to the camera body 100 andthe user turns on the power of the camera body 100, the power supply 160supplies a power to the interchangeable lens 200 via the body mount 150and the lens mount 250 (S11). The camera controller 140 requests thelens controller 240 to transmit authentication information about theinterchangeable lens 200 (S12). The authentication information about theinterchangeable lens 200 includes information about whether or not theinterchangeable lens 200 is mounted and information about whether or notan accessory is attached. The lens controller 240 responds to the lensauthentication request from the camera controller 140 (S13).

The camera controller 140 then requests the lens controller 240 toperform an initializing operation (S14). In response to this, the lenscontroller 240 performs the initializing operation such as resetting ofa diaphragm and resetting of the OIS lens 220. Thereafter, the lenscontroller 240 transmits information about the completion of the lensinitializing operation back to the camera controller 140 (S15).

The camera controller 140 requests the lens controller 240 to transmitlens data (S16). The lens data is stored in the flash memory 242. Thelens data includes characteristic values specific to the interchangeablelens 200 such as a lens name, an F-number, a focal length and linkinformation. The lens controller 240 reads the lens data from the flashmemory 242 and transmits it back to the camera controller 140 (S17). Thecamera body 100 obtains the link information at the recordingpreparation stage in such a manner, so that the camera body 100 canrecognize the magnification variation ratios on the positions of thezoom lens 210 at the recording preparation stage.

When the camera controller 140 obtains the lens data of theinterchangeable lens 200 mounted to the camera body 100, it is in therecording enabled state. The camera controller 140 in this stateperiodically requests the lens controller 240 to transmit lens statusdata indicating the status of the interchangeable lens 200 (S18). Thelens status data includes, for example, zoom magnification informationof the zoom lens 210, position information about the focus lens 230 andaperture value information. In response to this request, the lenscontroller 240 transmits the requested lens status data back to thecamera controller 140 (S19).

The camera system 1 according to the first embodiment transmits the linkinformation to the camera body 100 from the interchangeable lens 200 atthe recording preparation stage. As a result, even when anyinterchangeable lens having any magnification change characteristics ismounted to the camera body 100, the camera body 100 can transmit theinstruction for performing the suitable wobbling control on therespective positions of the zoom lens 210 to the interchangeable lens200.

1-3-2. Wobbling Operation in Recording of Moving Images

The wobbling operation in the recording of moving images is describedwith reference to FIGS. 8 and 9. FIG. 8 is a diagram illustratingtransmission/reception timing of signals between camera body 100 and theinterchangeable lens 200 in the wobbling control. FIG. 9 is a flowchartillustrating an algorithm for determining amplitude in the wobblingcontrol.

The transmission/reception of commands between the camera body 100 andthe interchangeable lens 200 in the wobbling control in the camerasystem 1 according to the first embodiment is described with referenceto FIG. 8. The user can set the camera system 1 into a moving imagerecording mode by operating the mode dial 131. When the moving imagerecording mode is set, the camera controller 140 stands by until itreceives an instruction for starting the moving image recording from theuser. At this time, the camera body 100 and the interchangeable lens 200already synchronize with each other. As one example of thetransmission/reception of data during the synchronization, the cameracontroller 140 transmits a request signal for requesting informationabout the position of the zoom lens 210 on the optical axis to theinterchangeable lens 200 (t1). When receiving the request signal, thelens controller 240 obtains the information about the position of thezoom lens 210 on the optical axis from the detector 212 so as totransmit it to the camera body 100 (t2).

At this time point, for example, when the camera controller 140 receivesthe instruction for starting the moving image recording from the userand determines that the wobbling control of the focus lens 230 should beperformed, it transmits a wobbling instruction command for instructingthe wobbling to the interchangeable lens 200 via the body mount 150(t3). The wobbling instruction command is a command for instructingamount of movement, a moving direction and amplitude at the time of thewobbling of the focus lens 230 (details of a method for determining thewobbling amplitude are described later). When obtaining the wobblinginstruction command, the lens controller 240 controls the focus motor233 so that the focus lens 230 is driven according to the commandcontents.

After transmitting the wobbling instruction command to theinterchangeable lens 200, at next exposure timing, the camera controller140 transmits the request signal to the interchangeable lens 200 (t4).When receiving the request signal, the lens controller 240 obtains theinformation about the position of the zoom lens 210 on the optical axisfrom the detector 212 and transmits it to the camera body 100 (t5).

When the camera controller 140 receives the information about theposition of the zoom lens 210 on the optical axis and determines thatthe position of the zoom lens 210 is not particularly changed and a newwobbling instruction command does not have to be transmitted, ittransmits a request signal to the interchangeable lens 200 at nextexposure timing (t6). When receiving the request signal, the lenscontroller 240 obtains the information about the position of the zoomlens 210 on the optical axis from the detector 212 and transmits it tothe camera body 100 (t7).

When the camera controller 140 receives the information about theposition of the zoom lens 210 on the optical axis and determines that anew wobbling instruction command should be transmitted due to asituation such that the position of the zoom lens 210 is changed, ittransmits the wobbling instruction command to the interchangeable lens200 at next exposure timing (t8).

The camera controller 140 receives also information about the positionof the focus lens 230 on the optical axis at a cycle correlated with theexposure timing (not shown). Further, the camera controller 140calculates an AF evaluation value at each exposure timing. The cameracontroller 140 makes a determination while linking the information aboutthe positions of the focus lens 230 with the AF evaluation values on therespective positions. As a result, the camera controller 140 candetermine the focus position of the focus lens 230.

By repeating such a control, the camera system 1 performs the autofocuscontrol by means of the wobbling.

The algorithm for determining the wobbling amplitude when the camerabody 100 according to the first embodiment generates the wobblinginstruction command for performing the wobbling control of the focuslens 230, is described below with reference to FIG. 9. The user can setthe camera system 1 into the moving image recording mode by operatingthe mode dial 131.

When the moving image recording mode is set, the camera controller 140obtains information about a position of the zoom lens 210 at the cyclecorrelated with the exposure timing of the CCD image sensor 110 (S31).The camera controller 140 determines whether or not the wobbling controlis necessary (S32). When the wobbling control is necessary, the cameracontroller 140 obtains magnification variation ratio linked with theobtained position information based on the current position informationabout the zoom lens 210 obtained at step S31 and the link informationobtained at the recording preparation stage (step S17 in FIG. 7). Thecamera controller 140 then determines whether or not the magnificationvariation ratio is more than a predetermined value (S33).

When the magnification variation ratio is determined as being not morethan the predetermined value (No at S33), the camera controller 140determines the wobbling amplitude of the focus lens 230 to a normalamplitude value C (S34). In this case, for example, the cameracontroller 140 determines the wobbling amplitude to be 80 (μm) as thenormal amplitude value C. On the other hand, when the magnificationvariation ratio is determined as being more than the predetermined value(Yes at S33), the camera controller 140 determines the wobblingamplitude of the focus lens 230 to a value D lower than thepredetermined value (S35). For example, the camera controller 140determines the wobbling amplitude to be 60 (μm) as the amplitude valueD. The camera controller 140 transmits the wobbling control commandincluding the determined amplitude value to the interchangeable lens 200so as to drive the focus lens 230 (S36).

The camera system 1 according to the first embodiment generates thewobbling control command based on the link information in theinterchangeable lens 200 and the information about the position of thezoom lens 210 on the optical axis. This is because the suitable wobblingcontrol method varies according to the link information and themagnification variation ratio determined based on the position of thezoom lens 210 on the optical axis. Therefore, the camera system 1generates the wobbling control command based on the link information inthe interchangeable lens 200 and the information about the position ofthe zoom lens 210 on the optical axis so as to generate the suitablewobbling control command moment to moment.

The camera system 1 according to the first embodiment determines thewobbling amplitude according to the information about the variation inthe magnification managed in relation with the position of the zoom lens210 on the optical axis. This is because the suitable wobbling amplitudealso changes according to a difference of the variation in themagnification. Therefore, the wobbling amplitude is controlled accordingto the information about the variation in the magnification managed inrelation with the position of the zoom lens 210 on the optical axis, sothat the camera system 1 can realize more suitable wobbling control.

When the zoom lens 210 is located at a position where the magnificationvariation ratio becomes higher than the predetermined value, the camerasystem 1 according to the first embodiment reduces the amplitude in thewobbling control of the focus lens 230 to an amplitude lower than thenormal amplitude. This is because, when the magnification variationratio is high, if the wobbling control is performed with the wobblingamplitude maintained at a normal amplitude, the variation in themagnification becomes noticeable and thus a recorded image becomesunsightly. When the magnification variation ratio becomes high, thewobbling amplitude is reduced to be lower than the normal value, so thatthe camera system 1 can realize the recording of an easily viewableimage in which variation in the magnification is unnoticeable.

The camera system 1 according to the first embodiment determines theamplitude in the wobbling of the focus lens 230 according to whether ornot the magnification variation ratio on the current position of thezoom lens 210 is higher than the predetermined value. However, thecamera system 1 doses not have to always have such a configuration. Forexample, the configuration may be such that factors to be multiplied bythe amplitude in the wobbling control of the focus lens 230 are relatedto the respective positions of the zoom lens 210 on the optical axis. Asa result, since the amplitude in the wobbling control can be determinedfor the respective positions of the zoom lens 210, the configuration canaccurately cope with an influence of the variation in the magnificationaccording to the positions of the zoom lens 210 on the optical axis.

1-3-3. Hill Climbing Autofocus Operation

The camera system 1 can perform the hill climbing autofocus operation inthe recording of moving images and still images according to user'sinstructions. Even when the hill climbing autofocus operation isperformed, the camera system 1 obtains the position information aboutthe zoom lens 210 every exposure timing, similarly to the case of thewobbling control of the focus lens 230. Further, when the drive speed ofthe focus lens 230 in the hill climbing autofocus operation isdetermined, the camera system 1 uses the magnification variation ratioinformation about the respective positions of the zoom lens 210.

The algorithm for determining the drive speed of the focus lens 230 inthe hill climbing autofocus operation of the camera system 1 isdescribed with reference to FIG. 10. FIG. 10 is a flowchart describingthe algorithm for determining the drive speed of the focus lens 230 inthe hill climbing autofocus operation of the camera system 1.

The user can set the camera system 1 into the moving image recordingmode by operating the mode dial 131. When the moving image recordingmode is set, the camera controller 140 obtains the position informationabout the zoom lens 210 at the cycle correlated with the exposure timingof the CCD image sensor 110 (S41). The camera controller 140 determineswhether or not the hill climbing autofocus control is necessary (S42).When the hill climbing autofocus control is necessary, the cameracontroller 140 obtains the magnification variation ratio linked with theobtained position information based on the current position informationabout the zoom lens 210 obtained at step S41 and the link informationobtained at the recording preparation stage (step S17 in FIG. 7). Thecamera controller 140 then determines whether or not the magnificationvariation ratio is more than a predetermined value (S43).

When the magnification variation ratio is determined as being not morethan the predetermined value (No at S43), the camera controller 140determines the drive speed of the focus lens 230 to a normal speed E(S44). On the other hand, when the magnification variation ratio isdetermined as being more than the predetermined value (Yes at S43), thecamera controller 140 determines the drive speed of the focus lens 230to a value F lower than the normal speed (S42).

When the magnification variation ratio on the position of the zoom lens210 is more than the predetermined value in the hill climbing autofocuscontrol, the camera system 1 according to the first embodiment sets thedrive speed of the focus lens 230 to a lower value than the normalvalue. As a result, even when the focus lens 230 passes through thefocus point, the camera system 1 can reduce the passing amount in thehill climbing autofocus control. As a result, even when the zoom lens210 is located at the position where the magnification variation ratiobecomes large, the camera system 1 can make it comparatively hard forthe user to feel the variation in the magnification.

In the camera system according to the first embodiment, theinterchangeable lens 200 stores the link information which links theinformation about the position of the zoom lens 210 on the optical axiswith the information about the variation in the magnification, and thecamera body 100 determines the amplitude of the focus lens 230 in thewobbling control and the drive speed of the focus lens 230 in the hillclimbing autofocus control based on the link information obtained fromthe interchangeable lens 200 and the position of the zoom lens 210 onthe optical axis. As a result, when moving images are recorded, thesuitable autofocus control can be performed according to the state ofthe zoom lens 210. Therefore, an image in which variation in themagnification is unnoticeable can be recorded.

2. Second Embodiment

In the second embodiment, another method for determining the amplitudevalue in the wobbling control is described. In the example of the firstembodiment shown in FIG. 9, the normal amplitude value C and the reducedamplitude value D are provided, and the amplitude value to be adopted isdetermined based on the magnification variation ratio corresponding tothe position of the zoom lens 210. In another example, every time whenthe focus lens 230 is tried to be driven, the amplitude value may becalculated according to the position of the zoom lens 210 at that time.The algorithm is concretely described below with reference to FIG. 11.

When the moving image recording mode is set, the camera controller 140obtains the position information about the zoom lens 210 at the cyclecorrelated with the exposure timing of the CCD image sensor 110 (S51).At this time, the aperture value and the condition of a subject areobtained. The camera controller 140 determines whether or not thewobbling control is necessary (S52). When the wobbling control isnecessary, the camera controller 140 calculates an amplitude value Gbased on the position information about the zoom lens 210 obtained atstep S51, the aperture value and the condition of a subject (S53).

The camera controller 140 calculates a limit amplitude H as an upperlimit value of the amplitude on the position of the zoom lens 210obtained at step S51 (S54). The limit amplitude H is obtained by thefollowing manner, for example. A magnification variation ratio I relatedto the obtained current position information is obtained by referring tothe link information obtained at the recording preparation stage (stepS17 in FIG. 7) based on the current position information about the zoomlens 210 obtained at step S51. The limit amplitude H (μm) is obtained byusing the magnification variation ratio I (%) corresponding to thecurrent zoom position and a predetermined magnification variation ratioJ (%) according to the following calculating formula. The predeterminedmagnification variation ratio J (%) is an upper limit of the allowablemagnification variation ratio in the case where the wobbling control isperformed with the amplitude 80 μm.

H=(J/I)×80(μm)

The camera controller 140 compares the amplitude value G calculated atstep S53 with the limit amplitude H calculated at step S54. When theamplitude value G is not more than the limit amplitude H, the cameracontroller 140 adopts the amplitude G (S56). When the amplitude value Gis more than the limit amplitude H, the camera controller 140 adopts thelimit amplitude H (S57). The camera controller 140 transmits a wobblingcontrol command including the adopted amplitude value to theinterchangeable lens 200 so as to drive the focus lens 230 (S58).

With such control, the magnification variation ratio can be reduced tobe not more than the predetermined value (J) regardless of the positionof the zoom lens 210. When moving images are recorded, the automaticfocus regulation can be suitably performed according to the state of thezoom lens 210. As a result, the variation in the magnification variationratio of a subject image captured on the CCD image sensor 110 becomesunnoticeable.

In the second embodiment, the amplitude value in the wobbling control iscalculated so that the magnification variation ratio becomes thepredetermined value or less. The drive speed of the focus lens 230 inthe hill climbing autofocus control may be calculated so that themagnification variation ratio becomes the predetermined value or less.

The aforementioned embodiments mainly describe the control in therecording operation of the camera system 1. However, the embodiment isnot limited to the recording operation. For example, the aforementionedcontrol may be applied to an operation in capturing a through image.

3. Correspondence of Terms

The drive mechanism 211 is one example of a zoom driver. The focus motor233 is one example of a focus driver. The flash memory 242 is oneexample of a storage unit. The combination of the camera controller 140and the body mount 150 is one example of a first obtaining unit and atransmission unit. The detector 212 is one example of a second obtainingunit. The camera controller 140 is one example of a generating unit.

Although the description has been made in connection with specifiedembodiments thereof, many other modifications, corrections andapplications are apparent to those skilled in the art. Therefore, thepresent embodiment is not limited by the disclosure provided herein butlimited only to the scope of the appended claims. The present disclosurerelates to subject matter contained in U.S. Patent Application No.61/160,010, filed on Mar. 13, 2009 and Japanese Patent Application No.2009-104996, filed on Apr. 23, 2009, which are expressly incorporatedherein by reference in its entirety.

INDUSTRIAL APPLICABILITY

The present embodiment can perform the suitable autofocus controlaccording to the state of the zoom lens, and is useful for theinterchangeable lens, the camera body and the camera system such as adigital still camera and a digital video camera.

1. An interchangeable lens comprising: a zoom lens operable to change asize of a subject image; a zoom driver operable to drive the zoom lensalong an optical axis; a focus lens operable to change a focus state ofthe subject image; a focus driver operable to drive the focus lens alongthe optical axis; and a storage unit operable to store link information,the link information including a plurality of magnification variationinformation and a plurality of position information, each of theposition information indicating a position of the zoom lens on theoptical axis, each of the magnification variation informationrepresenting a variation in magnification caused by movement of thefocus lens advancing and retreating on the optical axis when the zoomlens is at a position indicated by position information, the linkinformation linking the position information with information about thevariation in magnification, wherein the magnification variationinformation is obtained based on a predetermined movement amount of thefocus lens advancing and retreating on the optical axis.
 2. Aninterchangeable lens comprising: a focus lens operable to change a focusstate of a subject image; a focus driver operable to drive the focuslens along an optical axis; and a storage unit operable to storemagnification variation information, the magnification variationinformation representing a variation in magnification caused by movementof the focus lens advancing and retreating on the optical axis, whereinthe magnification variation information is obtained based on apredetermined movement amount of the focus lens advancing and retreatingon the optical axis.